Timer controlled apparatus adapted to feed and measure materials



June 23, 1953 F. A. CRAIGZ ETAL 2,643,026

. TIMER CONTROLLED APPARATUS ADAPTED T0 FEED AND MEASURE MATERIALS Filed April 2, 1947 5 Sheets-Sheet l M E M W I v 1 F. A. CRAIG EI'AL 2,643,026 TIMER CONTROLLED APPARATUS ADAPTED TO FEED AND MEASURE MATERIALS June 23, 1953 Filed April 2, 1947 3 Sheets-Sheet 2 III ll INVENTORS 71mins fl. [ru f B 0/01 lfarz/eq 7t ATTORNEY TIMER LED A ARATUS ADAPTED T0 FEED AND MEA E MATERIALS 3 Sheets-Sheet 5 June 23, 1953 F. A. cams EI'AL 2,643,026

CONTROL Filed April 2, 1947 w O O C 70a 7 I. I .I 74 55a o 7g T l "H 71a 4 9 55a 44115 4211 70 Q I 31' 69 65 V, [a MHHIIII I o v 16 2'54 INVENTORS Tz'uuas 17. (rag mhlwl liar/fly ATTORNEY Patented June 23, 1953 TIMER CONTROLLED APPARATUS ADAPTED T FEED AND MEASURE MATERIALS Francis A. Craig, Seneca Falls, and ohn H. Garvey, Brooklyn, N. Y., assignors to Cragar Packaging Co., Inc., Brooklyn, N. Y., a corporation of New York Application-AprilZ, 1947, Serial No. 739,024

The present invention relates to feeding machines and more particularly to machines adapted to feed accurately determined quantities of powdered, pulverized, granular, pasty, and other materials.

It is generally desirable to feed materials such as the above directly into cartons, tubes or other containers in which the material is to be sold. In connection with such feeding or filling opera-' tions it is most desirable to measure the various materials with a high degree of exactness or accuracy. If the feeding and measuring gives short measure, the manufacturer will be liable to prosecution for violation of the law; if excessive measure is given the material will overflow Claims. (01. 222-70) for feeding material it has heretofore proven difficult to obtain practically instantaneous startillg and stopping of auger at any given instant of time or position of the auger. Where friction plate clutches or couplings are utilized to control rotation of the feed screw or auger the plates are subjected to excessive wear and, due to plate slippage, this type of coupling means is not well adapted to effect instantaneous starting and stopping of screw rotation at a desired instant. It has been attempted to remedy the objection to friction plate types of couplings by utilizing clutches or couplings of more positive type, but such devices are generally dependent upon the rotation of two fixed points, which means that the auger or screw is not readily engaged and disengaged with a driving means at any angular position of the drive means.

The present invention aims to provide new and improved feeding and measuring mechanisms which are adapted toinstantly start and stop at any instant of time or at any point inthe actuation of a feed screw, auger or other feeding means. The invention further contemplates-the provision of means adapted to accurately and continuously control the feeding and non-feedingperiods of operation of a feeding machine and to facilitate selective determination of these periods.

An object of the present invention is to provide new and improved feeding and measuring means. Another object of the invention is to provide a feeding apparatus or machine adapted to fill receptacles with a high degree of accuracy.

Another object of the invention is to provide a feeding or measuring machine embodying improved actuating mechanism.

Another object of the invention is to provide a new and improved means or mechanism for controlling the operation of a feeding or measuring machine.

A further object of the invention is to provide new and improved means for varying the periods of operation of a feeding or measuring device.v

A still further object of the invention is to provide a feeding or measuring machine of relatively compact and simple construction.

' Other and further objects of the invention will be obvious upon an understanding of the illustrative embodiment about to be described, or will be indicated in the appended claims, and various advantages not referred to herein will occur to one skilled in the. art upon employment of the invention in practice.

A preferred embodiment of the invention has been chosen for purposes of illustration and description and is shown in the accompanying drawings, forming a part of the specification, wherein:

Fig. 1 is a perspective view, partly broken away showing one embodiment of the invention;

Fig. 2 is a top plan view of the apparatus shown in Fig. 1; 1

Fig. 3 is a sectional view taken along the line 3-3 of Fig. 2;

Fig. 4 is a sectional view taken along the line 1-4 of Fig, 2

Fig. 5 is a sectional view'taken along the line 5-5 of Fig. 4;

Fig. 6 is a sectional view taken along the line 6-6 of Fig. 5;

'Fig. 7 is a sectional view taken along the line I 'l-lof Fig. 5;

Fig. 8 .is an elevational View of a preferred form of actuating mechanism for the construction illustrated in Fig. 4; and

Fig. 9 is a schematic and diagrammatic representation showing one form of'electrical ontrolling means. 1

For purposes of illustration and description the present invention will be described chiefly with reference to a material feeding or measuring machine of the rotary screw or auger type. V,

The general arrangement of such a machine may be as illustrated in Fig. 1 of the drawings wherein there is disclosed a table or framework l upon which is mounted an upwardly extending framework 2 supporting a hopper 4. The hopper 4 may be bolted to the top plate 6, with a felt gasket 9 intermediate the hopper and the top plate. The hopper 4 is adapted to receive and contain the particular material which is to be fed into receptacles or containers (not shown), the material being supplied to the hopper through an opening 5 (Fig. 3) at the upper part of the hopper. A window 1 may be provided atone wall of the hopper to facilitate inspection of the. interior thereof and to insure maintaining an. ade= quate supply of material in the hopper.

A tubular extension 8 shown projecting downwardly from the bin or hopper 4 is adapted to guide material from the interior of the hopper to a receptacle. An auger or screw-like device In is provided at the interior of the tubular extension 8', with the outeredges of the. helix or screw thread portion fitting closely against the interior walls of the tubular extension 8. The auger or screw Hi preferably terminates at or closely adjacent the end of. the tubular extension 8 and may extend well into the hopper to facilitate movement of material through the hopper toward the tubular extension 8.

The auger I0 is shown connected with a rotatable shaft l l and rotates with the shaft I I. An agitator I3 is carried by an arm 14 connected to the auger shaft ll so that as the shaft Il rotates the auger II! it likewise rotates the agitator l3 and provides improved movement of material through the hopper by minimizing bridging thereof in the hopper.

As the shaft ll rotates, and thusturns the auger [0 together with the agitator l3, material moves from the interior of the hopper 4 toward and into the tubular extension 8. The material does not fall out through the tubular extension 8 as the latter is closed by the auger or screw member ID, which fits relatively closely with the walls of the tubular extension. The auger is normally surrounded by material to be metered or measured and as the auger rotates with the shaft ll, material feeds or moves through the tubular extension 8 toward the open end thereof. When the anger is at rest material does not feed through the tube 8 Thus rotation of the shaft H and auger Hi feeds material throu h the feed tube 8 and stopping the rotation of the shaft l I' and auger HT is effective to cut off the feed of material through the feed tube 8; intermittent rotation of the shaft H and auger I'll effects intermittent feed of material out of the tube 8. With auger rotation at a constant rate, e ual periods of rotation are effective to feed equal quantities of material out of the tube 8.

The auger l0 and shaft H are adapted to be rotated by an electric motor I'G located adjacent the hopper 4, at the upper part of the framework 2. The motor it may be mounted on a base portion ll, with the motor shaft vertically disposed. The motor ["6 is adapted to be moved bodily in a horizontal direction by a hand wheel [9 and threaded shaft 20 to vary the position of the motor from a driven shaft 22; when the hand wheel I9 and shaft 20' are rotated to shift the position of the motor [6 the pitch diameter of a variable speed pulley 2! is varied so that the rate of rotation of a pulley 23 connected with the variable pitch pulley 21 by the belt 24' is varied Constructions for varying the speed of rotation of a shaft by changingthepitchdiame- 4 ter of a variable speed pulley are commercially known.

The vertically disposed shaft 22 is mounted in bearings 25 and 26 adjacent its ends and has keyed thereto a pinion gear 21, the latter pinion gear 2'? meshing with; a second gear 28. The gear 28 is connected with and normally rotates aportion of a coupling or clutch mechanism 3| (Figs. 3 and 5). This clutch mechanism will be hereinafter described in detail. When the coupling'. or clutch mechanism 3! is operatively engaged with the gear 28 the shaft 25! is rotated; the latter shaft may be mounted in bearings 30 and 32 and serves to rotate a sprocket 34 fixed to the upper part thereof. The sprocket 34 drives the shaft it through the intermediation of chain 35, idler sprocket 31, and sprocket 36 carried by the shaft i I. The shaft 1 I may be maintained in position by suitable bearings 38 and 39. A preferred coupling or clutch mechanism 31 is shown in detail in Figs. 5, 6 and 7. As shown in these figures the gear 28 is secured by a key 46 to a housing member 42 so that the housing rotates with the gear 28. Both the gear 28 and housing 42 are shown extending around the shaft 29; with abronze bushing 4| forming a bearing surfacebetween the shaft 29 and the clutchhousing 42. It' is desired to intermittently rotate the shaft 29 to thereby effect intermittent rotation of the auger or screw member [0 car rier by the rotatable shaft H; the mechanismillustrated within anclimmediately adjacent the housing 42 is adapted to: facilitate intermittently connecting the normally continuously rotating gear 28 and housing 42 with the shaft 29.

Intermittent rotation of the shaft 29 may be obtained by connecting the shaft 29 with the continuously rotating housing 42 for desired periods of time. As shown, the shaft 29 has keyed thereto a hub member 43, the hub member being in turn keyed to a cam member 44 provided with a plurality of substantially flattened surfaces. Intermediate the flattened surfaces of the cam 44 and the continuously rotating housing 42 is shown; a plurality of rollers 42: and a. cage portion 5'6; The cage 50' and rollers 48 carried thereby are adapted to be moved circumferentiall y' with respect tothe vertically disposed shaft 29 to thus'position the rollers adjacent the low" points 01" mid-portions 46' of the flattened surfaces of the cam 44 or to move the rollers toward high portions 5? of the cam 44. In the relatior'iship shown in Fig. 7 the rollers 48 are dispo's'ed adjacentthe low points 46- of the cam surfaces so that rotation of the housing 42 with the gear 28, is not effective to rotate the cam 44 together with the hub 43 and shaft 29'. When the cage portion 50' is rotated so as towedge' the rollers-48 between high points 5! of the cam andthe walls of the housing 42,'the housing is in effect locked tothe shaft '29 and the driving gear is effective to rotate the shaft 29.

Movement of the cage to effect movement of the ro11ers48 and corresponding actuated and non-actuatedperiod's of theshaft it may be obtained by a campl'ate 5 3;,through the intermediation er, apivotpni 54 carried by a collar 55 and a combination pin-'and-slide member 51. The pin-andslide members! has integral therewithablock-like lower portion 60' disposed. within aradial slot 59 ofthe cage 50 and an out-' wa rdly extending-protuberance 8i fitted into an aperture 62 of the cam plat'e 53'. The collar ii-5 is fixedly secured to the hub- 43' and serves to maintain the cam plate 53 in downward position and to retain the pivot pin 54 in position. The

' cam plate '53 is secured to the collar 55 by a spring 58 secured to pins 6! and 62 carried by the cam plate 53 and collar 55. As shown, the spring 58 normally urges a step 64 on the cam plate 53 toward the pin 62 carried by the collar 55.

When force is applied against the cam step 64 in a direction tending to move the cam plate 53 in opposition to the effect of the spring 58, the cam plate rotates about the pivot pin 54 carried by the collar 55. The cam plate 53 thus acts as a lever fulcrumed at the pivot pin 54, and the pin-and-slide member 51 together with its integral block 68 tends to move about the pivot pin 54 in an opposite direction tothe cam step 56. The fiat side walls of the block-like portion 66 carried by the pin-and-slide press against an adjacent wall of the radial slot 59 in the cage 56 and tend to move or rotate the cage 55 along with the pin-and-slide. As pointed out hereinabove, movement of the cage 50 shifts the positions of the rollers 48 with respect to the high and low points of the cam 44 keyed to the shaft 26. The effect of the sprin 58 which connects the cam plate 53 with the roller 55 is to normally maintain the cage 58 and rollers 48 in such position that the rotating housing 4 2 and cam a l are engaged; thus the effect of the spring is to normally maintain the gear 28 operatively co nnected with and rotating the shaft 29. Pressure applied against the cam step 64 moves the cage to place the rollers adjacent 10w points of the cam 64, and hence stops rotation of the shaft 26 which connects with and drives the feed auger l5.

Actuation or operation of the cam plate 53, to control rotation of the shaft 29 by intermittently disconnecting the driven parts of the coupling 33 from the continuously rotating gear 28 and housing 62, may be controlled by a solenoid 65, through the intermediation of a solenoid plunger 56, solenoid rod 51, lever 68, vertically adjustable sleeve 78, and finger member H. The lever 68 is pivotally mounted intermediate its ends upon a bracket or arm 13, the latter being suitably secured by bolts, welding or the like to the plate 5 which forms the upper platform of the machine. The lever 58 is connected at the solenoid end thereof with a spring 14, the spring 14 serving to normally retain one end of the lever 68 upwardly against an adjustable stop pin 16 carried by a bracket 11, When the solenoid 65 is energized the solenoid plunger 66 moves downwardly together with the connecting rod 61 in opposition to the effect of the spring 14. Downward movement of the solenoid plunger is effective to rotate the lever 68 about the pin 69 to elevate the opposite end 18 of thelever.

The end it of the lever 68 is preferably of forked or yoke-like construction and provided with inwardly extending pins 86 which project into an annular recess 82 of the sleeve 10. The sleeve i6 is provided with a keyway 83 adapted to receive and slide along the key 45 which is carried by the shaft 28 and extends through the hub 55 of the coupling member 3 I.

When the lever 68 is operated to elevate or lift the sleeve ill (by energizing the solenoid 6.5 of.

Fig. 4) the. finger member 1| pivotally secured therewith tends to assume a more nearly vertical position so that its free end 85 moves away from the step 64 of the cam plate 53. The spring 58 urges the cam plate 53 circumferentially so that the cam step 64 follows along with the fin-,

ger end 85 and approaches the pin 62 of the collar 55; thus the cage 58 is caused to rotate with the finger end 85 to shift the wedging rollers 48 toward high areas 5| of the cam member 44. In this-relationship the shaft 29 will be locked to the continuously rotating gear 28 and housing 42and the feed member in will be feeding material.

When the current of the solenoid 65 is cut off the sprin 14 serves to pull one end of the lever 68 upwardly and to urge the opposite end 18 thereof downwardly; this means that the sleeve ill will be moved downwardly and the end 85 of the finger member H pressed against the step 64 of the cam plate 53, in opposition to the effect of the interconnecting spring 58. When the sleeve 16 is in a downward position the finger H holds the cage 56 and wedge rollers 48 in unlocked position, as shown in Fig. '7; thus the shaft 29 and feed member lfl will be at rest and material will not be fed out of the tubular extension 8.

.While the construction hereinabove described with respect to the solenoid 65 and spring 14 has proven satisfactory in actual operation, a slightly modified and preferred arrangement is illustrated in Fig. 8. In this latter figure a spring 74a connected with the lever 88a serves to normally maintain the sleeve 16a in elevated position on the shaft 26a. A solenoid (not shown) which connects with the solenoid rod 61a serves to maintain the solenoid end of the lever 68a in elevated position, to thus maintain the opposite end Eta and sleeve 76a in downward position. In the modified form of Fig. 8 the positions of the solenoid and spring are, in effect, interchanged. The construction of Fig. 8 is preferred for the reason that it has proven quite effective in controlling the operation of the coupling means 3! in those instances where there is a heavy load of material in the hopper 4. This latter construction, of course, requires that the solenoid be energized when the clutch or coupling means 3! is disengaged or unlocked from the rotating gear 28a and housing 42a. When the solenoid is energized the free end 85a of the finger member Ha presses against the step 640; of the cam plate 53a and the clutch is disengaged from the housing 42a and gear 28a. When the solenoid which actuates the solenoid rod 61a is deenergized the spring l'4a serves to elevate the sleeve a and move the free end a of the finger member Ha away from the step 64a. of the cam plate 53a; in this relationship the spring which interconnects the cam plate 53a with the collar 55a is effective to rotate the roller cage to engage the housing 42a with the shaft 2911.

It is most desirable that the engaged and disengaged periods of the auger or feed member [8 be accurately, continuously and automatically controlled and one form of mechanism or apparatus for so controlling the actuation of the mechanism is illustrated in Fig. 9. This figure shows a schematic diagram or wiring diagram which is adapted to control the operation of the solenoid 55 (55a of Fig. 8). It will be clear from the foregoing description that the solenoid 65 is in turn effective to control operation of the feed member is, through the intermediation of shaft H, sprocket 56, drive chain 35, sprocket 34, shaft tively connected with the continually rotating gear 28a (Fig. 8) v When the motor starter switch 95 is manually closed, current from the power lines '96, 91 and 98 passes through suitable contacts and leads to the coils of the driving motor I6. In ac tual usage a single horsepower, three phas'e 220 volt motor has proven satisfactory. The effective speed of the drive belt 24 may be suitably adjusted, within designed limits. by the control handle I9 which is adapted to facilitate adjustment of the pitch diameter of the belt pulley 2|.

As shown in Fig. 9 tw'o take-off leads I and IOI convey current to one side of a suitable stepdown transformer I02. The step-down transforme'r H32 need not be utilized in instances where it is desired to utilize higher power on the mechanism for automatically controlling the operation of the solenoid 65, however it is believed that its use will generaliy be preferred in actual operation. The coil of the solenoid 65 is shown connected at one end with the take-cit lead I00 and at the other end with a suitable terminal block I06.

The mechanism for controlling the energized and deenergized periods or the solenoid 65, and thus the operating and non-operating periods of a feed device I0, may comprise a first timing or controlling mechanism for determining the period of dee'nergiz'ation of the solenoid and an additional timing or controlling mechanism for determining the period of energiaation of the solenoid. These two timing devices or mech anisms' are preferably so interconnected or interlockedtha t when either one of them reaches substantially the endof its effective period it is adap'tedto-initiate operation of the other.

"The apparatus shown at the lower left portion of Fig. 9 is adapted to control the period of deenergization of the clutch-controlling solenoid 65 The apparatus shown at the lower right portion of Fig.9 is adapted to control the period of energizatioh of thechitch-controlling solenoid 65.

Normally the toggle switches TI and T2 are in closed position, as well as the time delay relay stop switch I03 in the lead I04. The leads it and iii- 5 are connected with the secondary coiloroutlet side of the transformer I02. When either of the time delay relay start contactor switches ltli or r09 is momentarily closed current may now, for exampla'from the lead I05 through the toggle switch Ti and thence through the leads IH, IE2 and I 63, depending upon which-of the switches it?) or Ice is momentarily closed. Thence the current may flow through the lead I I4, timingdevice MI and lead H6 out to there= turn line I04; inaddition, current from the lead ,I I i-may pass through the lead I I'L'lead I It, coil of the relay RI, and lead I20 to the return line I04. Thus momentary closing of either of the start contactor switches I08 or I09 is effective to pass current through and operate the timing device MI and to energize the solenoid of the relay Rl. 2

Momentary eergization of the "relay RI by momentarily closing switches I08 or I09, closes the breaker arm 1-2-2 against the contact I23 and current may flow through the lead I05, switch Tl,'lead i-zt;breaker arm I28, lead I29, breaker arm I22, lead 'I'I9, 'relay RI, and lead 1-20 out to the return line I04.

The timing device or mechanism MI "will have been p're-set or will have had its timing interval selectively predetermined so that after the timin'g device-t ll has 'b'een in operation for the 'predetermined interval the breaker arm I28 momentarily moves away from the contact I30 and momentarily establishes contact with the point I3'l'; the momentary position of the breaker arm I28 is indicated by the dotted position of the breaker arm. When the breaker arm I28 momentarily interrupted the contact with the point I30, flow of current through the timing device MI and the relay RI was interrupted. M0- mentary contact of the breaker arm I28 with the contact point I3i allows current to flow from the lead I26, through the breaker arm I28 and lead I32 to the lead I34. From the lead I34 current may flow through the timing device M2 via the leads I36 and I3! to the return line I04 and. also may pass through the coil of the relay R2 via the leads I39 and I40 to the return lead I04. Thus-.the cutting on or inactivation of the apparatus shown at the lower left portion of Fig. 9 is effective to supply current to the mechanism shown at the lower right portion of Fig. 9.

Momentary energization of the coil of relay R2, due to momentary closing of the breaker arm I20 with the contact point I3I, enables the solenoid of the relay R2 to move the breaker arms I42 and I43 against the contact points I45 and I44, respectively. The breaker arms I42 and I43 open and close simultaneously and this is indicated diagrammatically by the dotted member I46 shown pivotally interconnecting the breaker arms I42 and I43. With the breaker arm I42 moved into contact with the point I45 current from the leads I25 and I2? may flow through the breaker arm I48, lead I49, breaker arm I42, lead I39, relay R2 and lead I40 to the return line I04. Current may also pass from the lead I34 through the timing device M2 via the leads I36 and 37. Thus momentary contact of the breaker arm 23 against the contact point I3I serves to momentarily energize the relay R2 and the relay R2 moves the breaker arm I42 so that current will continue to flow through the relay R2 and the timing device M2 even after the breaker arm I20 moves away from the point I3I.

Since the relay R2 also effects closing of the breaker arm I43 against the contact I44 current may flow from the line I0i through the coil of the solenoid65 via the lead IEO, breaker arm I43'and lead I52. As long as the relay R2 is energized, the solenoid 65 is energized and the latter solenoid is effective to control the position of the lever 68 which moves the sleeve 10 and controls the operation of the clutch or coupling means 3I. When the solenoid 65 (or 65a) is deenergized the spring I4 (or 74a) is effective on the lever member.

The timing mechanism or device M2 which controls the period of effectiveness or energization of the solenoid 65 may be pre-set or selectively adjusted so that the solenoid 65 will be energized for a desired period of time. When the selectively predetermined time interval of the "timing device M2 has elapsed the breaker arm I48 momentarily leaves the contact point I53 and establishes contact with the point I54, as indicated by the dotted line positioned at the lower right portion of Fig. 9. In this dotted position current from the lead I21 to the timing device M2 and relay R2 is momentarily interrupted and the breaker arms I42 and I43 move away from their respective contact points I45 and I44; the solenoid 65 is deenergized. Momentary cone tact 'o'f the breaker arm I48 with the contact point I54 allows current to flow from leads I25 and [27 through the lead I55, switch Tzand lead ill through the timing device MI and relay RI; the relay RI closes the breaker arm 422 against the contact point I23. At this time the solenoid controlling apparatus shown at the lower right portion of Fig. 9 is rendered ineiiective and the period controlling apparatus shown at the lower left portion of Fig. 9 is again rendered effective. Continuous repetition of the cycle occurs until such time as the circuit from the power source is interrupted. This interruption is normally achieved by momentarily opening the time delay relay stop switch Hi3, which may be positioned adjacent the foot of an operator.

The opening of either of the breaker arms l28 or M8 is eifective to stop the cycle substantially precisely at predetermined time instants or points and thus the action of the machine, which is controlled by the solenoid 65, is stopped at the exact point that either of the breaker arms 28 and M8 is opened. This is a most desirable feature as it insures control of the clutch 3! in exact accordance with the operation of the relays RI and R2; the clutch 3i cuts in and out in correspondence with the operation of the relays R! and R2 and there is no necessity for dependence upon certain clutch points coming into contact prior to engagement or disengagement of the clutch which operates the shaft 29 and feed member Hi.

Various scales may be used on the timers. for example, timers having ranges from zero up to sixty seconds maximum or from zero up to fifteen seconds maximum maybe utilized; The minimum periods of adjustmentgenerally obtainable with the timers are one-quarter second intervals, the timing adjustment being variable from minimum to maximum in one-quarter second intervals.

The present tandem type of time delay relay gives highly satisfactory results in obtaining precise periods of time control. The wiring of the clock mechanisms and the relays is such that by making momentary contact on the first relay, the clock may be set for any desired time period; at the end of its time period the circuit of the second relay is made. The clock mechanism of the second time delay relay may also be set for a desired predetermined interval. At the end of its time period. the clock of the second relay is effective to reestablish the circuit of the first relay and the cycle is automatically repeated. Thus there is obtained continuous re-cycling which continues until such time as the current from the power source is momentarily interrupted.

The timers M! and M2 may be of synchronous motor type and the particular frequency of alternating current will determine the equality of the time periods.

The tandem time delay relay is preferably so used that one relay provides a time interval during which an operator may transfer containers to and from the tubular filling extension 8; this being a period during the auger or feed member in does not operate. A second relay maybe used to establish a circuit for energizing the solenoid 85, the time period of energization of the solenoid being that during which the feed member or auger is rotated to feed material to a receptacle.

While electronic timing means embodying vacuum tubes and the like may be utilized for controlling the periods of energization and deenergization of a solenoid 65, the foregoing described type of control mechanism is preferred in commercial usage for the reason that its installation effective.

is and maintenance are more generally understood by workmen and electricians.

It will be seen that the present invention provides new and improved apparatus or mechanism adapted to feed and measure various materials with close accuracy. The apparatus and devices of the present invention are adapted to feed and measure various materials in continuous onand-off cycles to receptacles or containers; the apparatus initiates and continuously maintains alternating feeding and non-feeding periods or cycles. During feeding periods a machine feeds material for a definite time interval; the time interval may be selectively predetermined prior to initiating operation of the apparatus. Upon completion of a feeding period or cycle, whichis effective to feed or measure a definite quantity of material, a non-feeding period is instituted. The duration of the non-feeding period may likewise be selectively predetermined prior to setting the apparatus into operation. I

Either or both of the feeding and non-feeding intervals or periods may be pre-set or selectively predetermined and at the expiration of either one of these time periods actuating devices automatically initiate operation of the other period. Upon termination of a feeding period the nonfeeding period is automatically set into operation and upon termination of thenon-feeding period, the feeding period automatically becomes again Continuous re-cycling of feeding and non-feeding periods occurs. Since the duration of the two periods may be accurately pre-set, and since the quantity of material fed is dependent upon the duration of the time period where the rate of feed is constant, the quantity of the material fed may be accurately predetermined by suitable adjustment or selection of the time period. Different time periods may be selected for different types of materials or for materials of different densities or degrees of coarseness.

' Ease of adjustment for difierent sizes of receptacles or containers may be readily made by varying the rate of rotation of the driving motor or by varying the length of time during which a feed device is effective to feed material. The rate of rotation of the motor may alone be changed, the time duration of the feed may alone be adjusted, orboth the rate of rotation of the actuating motor and the time duration periods may be adjusted. For example, some motor speed adjustment mechanisms of the type disclosed herein are capable of adjustment to any one of three different rates of rotation; the time control mechanisms may be adjusted in one-quarter second intervals from minimum to maximum time periods. Adjustment for varying densities of materials may be readily made.

The present machine or apparatus is of relatively simple and compact construction and cocupies littlefloor space. Relatively complicated right angle drives are. eliminated and moving parts are so positioned that they are not likely to readily become contaminated or contacted by the material being fed.

The actuating mechanism including the coupling or clutch is of compact and relatively foolproof construction. The coupling or clutch cooperates with the present machine so that a feed member may be stopped at any point in its operation; whenever a predetermined time period expires and the solenoid or spring is efiective to engage or disengage the coupling mechanism, the coupling immediately is effective to actuate or cease actuation of the feed member operatively connected therewith. The present mechanism is not dependent upon two fixed points first coming into contact or moving outv of contact prior to instituting control of the material feeding member; this is a distinct advantage over what may be termed single revolution clutches.

As various changes may be made in the form, construction and arrangement of the parts herein without departing from the spirit and scope of the invention and without sacrificing any of its advantages, it is to be understood that all matter herein is to be interpreted as illustrative and not in a limiting sense.

Having thus described our. invention, we claim:

1. A machine for feeding and measuring materials, comprising the combination ofa rotatable feed screw, driving meansv to rotate said screw for feeding material, coupling means including a normally rotatable member operatively connected with the driving means and a movable member operatively connected with the. feed member, and movable into and out of engagement with. the rotatable member for operatively connecting and disconnecting the driving means and. the. feed screw, a first electrical timing device operatively connected with said movable member of the. coupling means to determine the time period. during which the coupling means and driving means are connected and said feed screw is rotated, a second electrical timing device operatively connected with said movable member of the coupling means to determine the time period during which the coupling means and driving means. are disconnected and said feed screw is not rotated, and

electrical means so interconnecting said first and second electrical timing devices. that either one automatically initiates operation. of the other upon reaching substantially the. end of its.respective time period.

2. A. machine for feedingv and measuring materials, comprising the combination of a feed screw, means for actuating said. feed. screw, a coupling device for operatively connecting and disconnecting the feed screw and the actuating means, an electrical timer operatively connected with the coupling device for determining-the time period during which said screwactuating means and coupling device are connected, a second electrical timer operatively connected with the couling device for determining the time period. during which said screw actuating means and coupling device are disconnected, and electrical relays so interconnected with. said electrical timers that when either of said timers reaches the end of i s time period the othertimer is automatically set into operation.

3. A machine for feeding and measuring materials, comprising the combination of a feed screw, means for actuating said feed screw, a coupling device for operatively connecting and disconnecting the feed screw and the actuating means, an electrical timer of selectively determinable time periods operatively connected with the coupling device for determining the time period during which said screw actuating means and coupling device are operatively connected, a second electrical timer of selectively determinable time periods operatively connected with the coupling, device. for. determining, the. time period during which. said. screw actuatin means and coupling device are operatively disconnected, and electrical relays so interconnected with said electrical timers that when either of said timers reaches the end of its selectively determined time period the other timer is, set into operation, said interconnected relays normally automatically efiecting continuous alternation of timers and continuous alternation of feeding and non-feeding periods of saidfeed screw.

4, A device for feeding materials, comprising the combination. of. a rotatable feed member, driving means to actuate said feed member, coupling means including a normally rotatable member operatively connected with. the driving means and a. member operatively connected with the feed member and. movable into and out of engagement with the rotatable member to intermittently rotate said feed member, a solenoid and a finger member connected therewith for actusting said movable member and connecting and disconnecting the driving means and the feed member, a timer operatively connected with said solenoid to determine the time period during which the coupling means and driving means are operatively connected, and an additional timer independent of said first timer operatively connected with said solenoid to determine the time period during which the coupling means and driving means are operatively disconnected.

5. In a machine for feeding and measuring materials, the combination of a feed screw, a coupling device for operatively connecting and disconnecting the feed screw with an actuating means, an electrical timer operatively connected with the coupling device for determining the time period during which said screw actuating means and coupling device are connected, a second electrical timer operatively connected with the coupling device for determining the time period during which said screw actuating means and coupling device are disconnected, and electrical relays so interconnected with said electrical timers that when either of said timers reaches the end of its time period the other timer is automatically set into operation.

FRANCIS A. CRAIG. JOHN H. GARVEY.

References Cited. in the file of this patent UNITED STATE-$- PATENTS Number Name Date 661,679 Wyckoff F Nov. 13, 1900 1,392,311 Egeland. Oct. 4, 1921 1,395,727 Odermatt Nov. 1, 1921 2,128,252 Johnson Aug. 30, 1938 2,299,007 Bundy Oct. 13, 1942 2,308,709 Newman Jan. 19, 1943 2,324,767 Cote July 20, 1943 2,352,183 Bullard June27, 1944 2,376,624 Sayre May 22, 1945 2,396,385 Plym Mar. 12, 1945 2,396,523 Nelsen ..o Mar. 12, 1946 

